Method for forming a multiple charge generating photorefractive polymer composite for hologram writing

What is claimed is: 1 . A photorefractive polymer composite comprising: a charge transporting polymer (CTP) matrix; and a photosensitizer comprising a quantum dot (QD) material with a first band gap coupled to a nanoparticle material with a second band gap greater than the first band gap; wherein the photosensitizer is configured to generate a plurality of free charges and to transfer the free charges to the CTP matrix in response to an incident photon on the polymer composite. 2 . The photorefractive polymer composite of claim 1 wherein the QD material comprises one of Graphene, lead sulfide (PbS), lead selenide (PbSe) and indium phosphide (InP). 3 . The photorefractive polymer composite of claim 1 wherein the nanoparticle material is one of TiO 2 , ZnO and ZnS. 4 . The photorefractive polymer composite of claim 1 wherein the first band gap of the QD material is configured such that an energy of each incident photon is an integral multiple of the first band gap. 5 . The photorefractive polymer composite of claim 4 wherein the first band gap is configured such that the energy of each incident photon is up to 5 times the first band gap. 6 . The photorefractive polymer composite of claim 1 wherein the first band gap of the QD material is configured such that an energy of each incident photon is at least 2.7 times the first band gap. 7 . The photorefractive polymer composite of claim 4 , wherein the energy of each incident photon is 2.33 eV and the first band gap is one of 0.59 eV, 0.77 eV and 1.175 eV. 8 . The photorefractive polymer composite of claim 1 wherein the plurality of free charges are generated based on impact ionization in the QD material. 9 . An apparatus comprising: a photorefractive (PR) polymer composite including; a charge transporting polymer (CTP) matrix, and a photosensitizer comprising a quantum dot (QD) material with a first band gap coupled to a nanoparticle material with a second band gap greater than the first band gap, a pair of electrodes contacted to opposing sides of the PR polymer composite to apply an external electric field across the PR polymer composite; a light modulator configured to receive image data of a plurality of 3D perspective views of an object from a plurality of fixed directions; a lens configured to focus an object beam transmitted through the light modulator for each 3D perspective view within the PR polymer composite from a first side of the PR polymer composite; and a reference beam directed within the PR polymer composite at each fixed direction from a second side of the PR polymer composite opposite to the first side and to interfere with the object beam within the PR polymer composite to impress an index pattern within the PR polymer composite of the 3D perspective view of the object at each fixed direction. 10 . The apparatus of claim 9 wherein the QD material comprises one of Graphene, lead sulfide (PbS), lead selenide (PbSe) and indium phosphide (InP). 11 . The apparatus of claim 9 wherein the nanoparticle material is one of TiO 2 , ZnO and ZnS. 12 . The apparatus of claim 9 wherein the photosensitizer is configured to generate a plurality of free charges and to transfer the free charges to the CTP matrix in response to an incident photon on the polymer composite. 13 . The apparatus of claim 12 wherein the first band gap of the QD material is configured such that an energy of each incident photon is an integral multiple of the first band gap. 14 . The apparatus of claim 12 wherein the first band gap of the QD material is configured such that an energy of each incident photon is at least 2.7 times the first band gap. 15 . The apparatus of claim 13 wherein the energy of each incident photon is 2.33 eV and the first band gap is one of 0.59 eV, 0.77 eV and 1.175 eV. 16 . The apparatus of claim 9 wherein the light modulator is configured to receive image data of a portion of each 3D perspective view from each fixed direction and wherein the lens is configured to focus the object beam for the portion of each 3D perspective view to a cross-sectional area within the PR polymer composite. 17 . The apparatus of claim 16 wherein the reference beam is to interfere with the object beam to impress the index pattern within the cross-sectional area of the PR polymer composite of the portion of the 3D perspective view from the fixed direction. 18 . The apparatus of claim 9 wherein the reference beam and the object beam are obtained by splitting a single laser beam. 19 . The apparatus of claim 9 wherein the plurality of 3D perspective views are generated from a single perspective view of the object. 20 . A method comprising: combining a charge transporting polymer (CTP), a plasticizer, a non-linear optical (NLO) chromophore, and a quantum dot (QD) sensitizer in a solvent to form a mixture; sonicating the mixture; evaporating the solvent to obtain a composite; and melt processing the composite between a pair of electrodes to obtain a photorefractive polymer composite.